import copyreg
import os
import sys
import warnings

import numpy as np

import aesara
import aesara.scalar as aes
import aesara.tensor as aet
import aesara.tensor.basic
from aesara.compile import SharedVariable
from aesara.configdefaults import config
from aesara.graph.basic import Constant, Variable
from aesara.graph.type import CType
from aesara.misc.safe_asarray import _asarray
from aesara.tensor.shape import (
    register_shape_c_code,
    register_shape_i_c_code,
    register_specify_shape_c_code,
)
from aesara.tensor.type import TensorType, complex_dtypes, discrete_dtypes
from aesara.tensor.type import values_eq_approx as tensor_values_eq_approx
from aesara.tensor.type import (
    values_eq_approx_remove_inf as tensor_values_eq_approx_remove_inf,
)
from aesara.tensor.type import (
    values_eq_approx_remove_inf_nan as tensor_values_eq_approx_remove_inf_nan,
)
from aesara.tensor.type import (
    values_eq_approx_remove_nan as tensor_values_eq_approx_remove_nan,
)
from aesara.tensor.var import TensorConstantSignature, _tensor_py_operators


# Make sure this is importable even if pygpu is absent
# (it will not work though)
try:
    import pygpu
    from pygpu import gpuarray
    from pygpu.elemwise import compare, elemwise2
except ImportError:
    pygpu = None

_context_reg = {}


def gpu_supported(data):
    """
    Is the following data supported on the GPU?

    Currently, only complex aren't supported.

    Parameters
    ----------
    data : numpy.ndarray or TensorVariable
           (it must have dtype and ndim parameter)
    """
    return str(data.dtype) not in complex_dtypes


def move_to_gpu(data):
    """
    Do we want to move this computation to the GPU?

    Currently, we don't move complex and scalar.

    Parameters
    ----------
    data : numpy.ndarray or TensorVariable
           (it must have dtype and ndim parameter)
    """
    # We don't support complex on the GPU
    if not gpu_supported(data):
        return False
    # We don't want scalars on the GPU.
    if data.ndim == 0:
        return False
    return True


class ContextNotDefined(ValueError):
    pass


def reg_context(name, ctx):
    """
    Register a context by mapping it to a name.

    The context must be of type `GpuContext` and the name can be
    anything hashable (but is usually a string). Only one context can
    be registered per name and the second registration for a given
    name will raise an error.

    Parameters
    ----------
    name : hashable object
        Name to associate the context with (usually a string)
    ctx : GpuContext
        Context instance

    """
    if name in _context_reg:
        raise ValueError(f"context name {name} is already defined")
    if not isinstance(ctx, gpuarray.GpuContext):
        raise TypeError("context is not GpuContext")
    _context_reg[name] = ctx


def get_context(name):
    """
    Retrive the context associated with a name.

    Return the context object mapped to `ref` that was previously
    register through :func:`reg_context`. Trying to get the context
    for an unregistered `ref` will raise a exception.

    Parameters
    ----------
    name : hashable object
        Name associated with the context we want (usually a string)

    """
    if name not in _context_reg:
        raise ContextNotDefined(f"context name {name} not defined")
    return _context_reg[name]


def list_contexts():
    """
    Return an iterable of all the registered context names.

    """
    return _context_reg.keys()


# Private method
def _name_for_ctx(ctx):
    for k, v in _context_reg.items():
        if v == ctx:
            return k
    raise ContextNotDefined("context is not registered")


# This is a private method for use by the tests only
def _unreg_context(name):
    del _context_reg[name]


class GpuArrayType(CType):
    """
    The type that represents an array on a gpu.

    The `dtype` indicates what scalar data type the elements of
    variables of this type will be.

    `broadcastable` indicates whether each dimension is broadcastable
    or not (to be broadcastable a dimension must always be of length
    1).

    The `context_name` is the name of the context on will values of
    variables of this type will be stored.

    Parameters
    ----------
    dtype : str
        The name of a numpy dtype
    broadcastable : tuple of bools
        A tuple that indicates both the number of dimensions (by its
        length) and whether those dimensions are broadcastable or not
        (by the boolean values).
    context_name : str
        The name of the context the that this type is attached to
        (default: None, which is the context specified by
        config.device).
    name : string, optional
        A name for the type that will be used in printouts.

    Attributes
    ----------
    dtype : str
        Data type used for scalar elements of variables.
    broadcastable : tuple of bools
        Indicates whether the dimensions are broadcastable or not.
    ndim : int
        The number of dimensions
    context_name : str
        The name of a gpu context on which variables will have their values.
    name : str
        A string used to print the type if given.
    typecode : int
        The gpuarray typecode for `dtype`

    See Also
    --------
    aesara.graph.type.Type

    """

    def __init__(self, dtype, broadcastable, context_name=None, name=None):
        # In case this was not provided and no global value is available
        self.dtype = str(dtype)
        self.broadcastable = tuple(bool(b) for b in broadcastable)
        self.ndim = len(self.broadcastable)
        self.name = name
        self.context_name = context_name
        # This will check that the passed context name is valid and registered.
        get_context(self.context_name)
        try:
            self.typecode = gpuarray.dtype_to_typecode(self.dtype)
        except gpuarray.GpuArrayException:
            raise TypeError(
                f"Unsupported dtype for {self.__class__.__name__}: {self.dtype}"
            )

    def clone(self, dtype=None, broadcastable=None):
        if dtype is None:
            dtype = self.dtype
        if broadcastable is None:
            broadcastable = self.broadcastable
        return self.__class__(
            dtype=dtype,
            broadcastable=broadcastable,
            context_name=self.context_name,
            name=self.name,
        )

    # This is a property to keep the type pickleable
    @property
    def context(self):
        """
        The context object mapped to the type's :attr:`context_name`.
        This is a property.

        """
        return get_context(self.context_name)

    def __repr__(self):
        # Inspired from TensorType.
        if self.name:
            return self.name
        else:
            b = self.broadcastable
            named_broadcastable = {
                tuple(): "scalar",
                (False,): "vector",
                (False, True): "col",
                (True, False): "row",
                (False, False): "matrix",
            }
            if b in named_broadcastable:
                bcast = named_broadcastable[b]
            elif any(b):
                bcast = str(b)
            else:
                bcast = f"{len(b)}D"
            return f"GpuArrayType<{self.context_name}>({self.dtype}, {bcast})"

    def filter(self, data, strict=False, allow_downcast=None):
        return self.filter_inplace(
            data, None, strict=strict, allow_downcast=allow_downcast
        )

    def filter_inplace(self, data, old_data, strict=False, allow_downcast=None):
        if isinstance(data, gpuarray.GpuArray) and data.typecode == self.typecode:
            # This is just to make this condition not enter the
            # following branches
            pass
        elif strict:
            if not isinstance(data, gpuarray.GpuArray):
                raise TypeError(f"{self} expected a GpuArray object.", data, type(data))
            if self.typecode != data.typecode:
                raise TypeError(
                    f"{self} expected typecode {int(self.typecode)} (dtype {self.dtype}), "
                    f"got {int(data.typecode)} (dtype {data.dtype})."
                )
            if self.context != data.context:
                raise TypeError("data context does not match type context")
            # fallthrough to ndim check
        elif allow_downcast or (
            allow_downcast is None
            and type(data) == float
            and self.dtype == config.floatX
        ):
            if not isinstance(data, gpuarray.GpuArray):
                data = np.array(
                    data, dtype=self.dtype, copy=False, ndmin=len(self.broadcastable)
                )
            else:
                data = gpuarray.array(
                    data,
                    dtype=self.typecode,
                    copy=False,
                    ndmin=len(self.broadcastable),
                    context=self.context,
                )
        else:
            if not hasattr(data, "dtype"):
                converted_data = _asarray(data, self.dtype)
                # We use the `values_eq` static function from TensorType
                # to handle NaN values.
                if TensorType.values_eq(
                    np.asarray(data), converted_data, force_same_dtype=False
                ):
                    data = converted_data

            up_dtype = aes.upcast(self.dtype, data.dtype)
            if up_dtype == self.dtype:
                if not isinstance(data, gpuarray.GpuArray):
                    data = np.array(data, dtype=self.dtype, copy=False)
                else:
                    data = gpuarray.array(data, dtype=self.dtype, copy=False)
            else:
                raise TypeError(
                    f"{self} cannot store a value of dtype {data.dtype} "
                    "without risking loss of precision."
                )

        if self.ndim != data.ndim:
            raise TypeError(
                f"Wrong number of dimensions: expected {self.ndim}, "
                f"got {data.ndim} with shape {data.shape}.",
                data,
            )
        shp = data.shape
        for i, b in enumerate(self.broadcastable):
            if b and shp[i] != 1:
                raise TypeError(
                    "Non-unit value on shape on a broadcastable" " dimension.",
                    shp,
                    self.broadcastable,
                )
        if not isinstance(data, gpuarray.GpuArray):
            if (
                old_data is not None
                and old_data.shape == data.shape
                and (
                    # write() only work if the destitation is contiguous.
                    old_data.flags["C_CONTIGUOUS"]
                    or old_data.flags["F_CONTIGUOUS"]
                )
            ):
                old_data.write(data)
                data = old_data
            else:
                data = pygpu.array(data, context=self.context)
        return data

    def filter_variable(self, other, allow_convert=True):
        if hasattr(other, "_as_GpuArrayVariable"):
            other = other._as_GpuArrayVariable(self.context_name)

        if not isinstance(other, Variable):
            other = self.Constant(type=self, data=other)

        if other.type == self:
            return other

        if not isinstance(other.type, (TensorType, GpuArrayType)):
            raise TypeError("Incompatible type", (self, other.type))
        if other.type.dtype != self.dtype:
            raise TypeError("Incompatible dtype", (self.dtype, other.type.dtype))
        if other.type.ndim != self.ndim:
            raise TypeError(
                "Incompatible number of dimensions."
                f" Expected {int(self.ndim)}, got {int(other.ndim)}."
            )
        if other.type.broadcastable != self.broadcastable:
            if allow_convert:
                type2 = other.type.clone(broadcastable=self.broadcastable)
                other2 = type2.convert_variable(other)
            else:
                other2 = None
            if other2 is None:
                raise TypeError(
                    "Incompatible broadcastable dimensions."
                    f" Expected {other.type.broadcastable}, got {self.broadcastable}."
                )
            other = other2

        return other.transfer(self.context_name)

    @staticmethod
    def values_eq(a, b, force_same_dtype=True):
        if a.shape != b.shape:
            return False
        if force_same_dtype and a.typecode != b.typecode:
            return False
        a_eq_b = np.asarray(compare(a, "==", b))
        if a_eq_b.all():
            return True

        # maybe the trouble is that there are NaNs
        a = np.asarray(a)
        b = np.asarray(b)

        a_missing = np.isnan(a)
        if a_missing.any():
            b_missing = np.isnan(b)
            return np.all(a_eq_b + (a_missing == b_missing))
        else:
            return False

    @staticmethod
    def values_eq_approx(
        a, b, allow_remove_inf=False, allow_remove_nan=False, rtol=None, atol=None
    ):
        return values_eq_approx(a, b, allow_remove_inf, allow_remove_nan, rtol, atol)

    @staticmethod
    def may_share_memory(a, b):
        if not isinstance(a, gpuarray.GpuArray) or not isinstance(b, gpuarray.GpuArray):
            return False
        return pygpu.gpuarray.may_share_memory(a, b)

    def value_zeros(self, shape):
        return pygpu.gpuarray.zeros(shape, dtype=self.typecode, context=self.context)

    def __eq__(self, other):
        return (
            type(self) == type(other)
            and self.typecode == other.typecode
            and self.broadcastable == other.broadcastable
            and self.context_name == other.context_name
        )

    def convert_variable(self, var):
        vt = var.type
        if (
            type(self) == type(vt)
            and self.typecode == vt.typecode
            and self.ndim == vt.ndim
            and self.context_name == vt.context_name
            and all(
                sb == ob or ob for sb, ob in zip(self.broadcastable, vt.broadcastable)
            )
        ):
            return aet.patternbroadcast(var, self.broadcastable)

    def __hash__(self):
        return hash((type(self), self.typecode, self.broadcastable, self.context_name))

    def dtype_specs(self):
        """
        Return a tuple (python type, c type, numpy typenum) that corresponds
        to self.dtype.

        This function is used internally as part of C code generation.

        """
        try:
            return {
                "float16": (float, "npy_float16", "NPY_FLOAT16"),
                "float32": (float, "npy_float32", "NPY_FLOAT32"),
                "float64": (float, "npy_float64", "NPY_FLOAT64"),
                "bool": (int, "npy_bool", "NPY_BOOL"),
                "uint8": (int, "npy_uint8", "NPY_UINT8"),
                "int8": (int, "npy_int8", "NPY_INT8"),
                "uint16": (int, "npy_uint16", "NPY_UINT16"),
                "int16": (int, "npy_int16", "NPY_INT16"),
                "uint32": (int, "npy_uint32", "NPY_UINT32"),
                "int32": (int, "npy_int32", "NPY_INT32"),
                "uint64": (int, "npy_uint64", "NPY_UINT64"),
                "int64": (int, "npy_int64", "NPY_INT64"),
                # 'complex128': (complex, 'aesara_complex128', 'NPY_COMPLEX128'),
                # 'complex64': (complex, 'aesara_complex64', 'NPY_COMPLEX64')
            }[self.dtype]
        except KeyError:
            raise TypeError(
                f"Unsupported dtype for {self.__class__.__name__}: {self.dtype}"
            )

    def get_shape_info(self, obj):
        return obj.shape

    def get_size(self, shape_info):
        if shape_info:
            return np.prod(shape_info) * np.dtype(self.dtype).itemsize
        else:
            return np.dtype(self.dtype).itemsize

    def c_element_type(self):
        return pygpu.gpuarray.dtype_to_ctype(self.dtype)

    def c_declare(self, name, sub, check_input=True):
        return f"""
        PyGpuArrayObject *{name};
        """

    def c_init(self, name, sub):
        return f"{name} = NULL;"

    def c_extract(self, name, sub, check_input=True, **kwargs):
        # TODO I don't check broadcast stuff for now.
        return """
        %(name)s = NULL;
        if (py_%(name)s == Py_None) {
            PyErr_SetString(PyExc_ValueError, "expected a GpuArray, not None");
            %(fail)s
        }
        /* First check if we are the base type exactly (the most common case),
           then do the full subclass check if needed. */
        if (py_%(name)s->ob_type != &PyGpuArrayType &&
            !PyObject_TypeCheck(py_%(name)s, &PyGpuArrayType)) {
            PyErr_SetString(PyExc_ValueError, "expected a GpuArray");
            %(fail)s
        }
        %(name)s = (PyGpuArrayObject *)py_%(name)s;
        Py_INCREF(%(name)s);
        """ % {
            "name": name,
            "fail": sub["fail"],
        }

    def c_cleanup(self, name, sub):
        return "Py_XDECREF({name}); {name} = NULL;".format(name=name)

    def c_sync(self, name, sub):
        return """
        if (!%(name)s) {
            Py_XDECREF(py_%(name)s);
            Py_INCREF(Py_None);
            py_%(name)s = Py_None;
        } else if ((void *)py_%(name)s != (void *)%(name)s) {
            Py_XDECREF(py_%(name)s);
            py_%(name)s = (PyObject *)%(name)s;
            Py_INCREF(py_%(name)s);
        }
        """ % {
            "name": name
        }

    def c_init_code(self, **kwargs):
        # We don't actually need the numpy API except in
        # HostFromGpu and GpuFromHost and those case will be covered
        # by the TensorType parameter
        return ["import_pygpu__gpuarray();"]

    def c_headers(self, **kwargs):
        # We need arrayobject for the PyArrayDescr struct def
        # (even if we just use a pointer to it in a function def)
        return [
            "<gpuarray/array.h>",
            "<gpuarray/kernel.h>",
            "<gpuarray/error.h>",
            "<gpuarray/buffer.h>",
            "<gpuarray/buffer_blas.h>",
            "<numpy/arrayobject.h>",
            "<gpuarray_api.h>",
        ]

    def c_header_dirs(self, **kwargs):
        other_dirs = []
        for dir_to_add in ["Library/include", "include"]:
            alt_inc_dir = os.path.abspath(
                os.path.normpath(sys.exec_prefix + "/" + dir_to_add)
            )
            if os.path.exists(alt_inc_dir) and os.path.isdir(alt_inc_dir):
                other_dirs.append(alt_inc_dir)
        return [pygpu.get_include(), np.get_include()] + other_dirs

    def c_lib_dirs(self, **kwargs):
        dirs = []
        for dir_to_add in ["Library/lib", "lib"]:
            alt_lib_dir = os.path.abspath(
                os.path.normpath(sys.exec_prefix + "/" + dir_to_add)
            )
            if os.path.exists(alt_lib_dir) and os.path.isdir(alt_lib_dir):
                dirs.append(alt_lib_dir)
        return dirs

    def c_libraries(self, **kwargs):
        return ["gpuarray"]

    def c_code_cache_version(self):
        ver = pygpu.gpuarray.abi_version()
        # we only use the major version since the minor revision are compatible.
        return (2, ver[0])


def values_eq_approx(
    a, b, allow_remove_inf=False, allow_remove_nan=False, rtol=None, atol=None
):
    if a.shape != b.shape or a.dtype != b.dtype:
        return False
    if str(a.dtype) in discrete_dtypes:
        return GpuArrayType.values_eq(a, b)
    else:
        if not (allow_remove_inf or allow_remove_nan):
            atol_, rtol_ = aesara.tensor.math._get_atol_rtol(a, b)
            if rtol is not None:
                rtol_ = rtol
            if atol is not None:
                atol_ = atol
            res = elemwise2(
                a,
                "",
                b,
                a,
                odtype=np.dtype("bool"),
                op_tmpl="res = (fabs(a - b) <"
                "(%(atol_)s + %(rtol_)s * fabs(b)))" % locals(),
            )
            ret = np.asarray(res).all()
            if ret:
                return True

        an = np.asarray(a)
        bn = np.asarray(b)
        return TensorType.values_eq_approx(
            an,
            bn,
            allow_remove_inf=allow_remove_inf,
            allow_remove_nan=allow_remove_nan,
            rtol=rtol,
            atol=atol,
        )


def values_eq_approx_remove_inf(a, b):
    return values_eq_approx(a, b, True)


def values_eq_approx_remove_nan(a, b):
    return values_eq_approx(a, b, False, True)


def values_eq_approx_remove_inf_nan(a, b):
    return values_eq_approx(a, b, True, True)


# This is to map ndarray-specific versions of these functions to the GPU.
EQ_MAP = {
    tensor_values_eq_approx: values_eq_approx,
    tensor_values_eq_approx_remove_inf: values_eq_approx_remove_inf,
    tensor_values_eq_approx_remove_nan: values_eq_approx_remove_nan,
    tensor_values_eq_approx_remove_inf_nan: values_eq_approx_remove_inf_nan,
}


# Add a reverse map too.
EQ_MAP.update(list((v, k) for k, v in EQ_MAP.items()))


class _operators(_tensor_py_operators):
    def _as_GpuArrayVariable(self, context_name):
        if self.type.context_name == context_name:
            return self
        else:
            from .basic_ops import GpuToGpu

            return GpuToGpu(context_name)(self)


@aet._as_tensor_variable.register(_operators)
def _as_tensor_operators(x, **kwargs):
    from aesara.gpuarray.basic_ops import host_from_gpu

    return host_from_gpu(x)


class GpuArrayVariable(_operators, Variable):
    """
    A variable representing a computation on a certain GPU.

    This supports all the operations that :class:`TensorType`
    supports.

    See Also
    --------
    Variable

    """

    # override the default
    def __repr_test_value__(self):
        return repr(np.array(aesara.graph.op.get_test_value(self)))


GpuArrayType.Variable = GpuArrayVariable


class GpuArraySignature(TensorConstantSignature):
    # might do something better if we can run the sum on the GPU, but
    # for now this will suffice.
    pass


class GpuArrayConstant(_operators, Constant):
    """
    A constant representing a value on a certain GPU.

    This supports all the operations that :class:`TensorType`
    supports.

    See Also
    --------
    Constant

    """

    def signature(self):
        return GpuArraySignature((self.type, np.asarray(self.data)))

    def __str__(self):
        if self.name is not None:
            return self.name
        try:
            np_data = np.asarray(self.data)
        except gpuarray.GpuArrayException:
            try:
                np_data = str(self.data)
            except Exception:
                np_data = "Unknown"
        return "GpuArrayConstant{%s}" % np_data


GpuArrayType.Constant = GpuArrayConstant


class GpuArraySharedVariable(_operators, SharedVariable):
    """
    A variable representing a shared value on a certain GPU.

    This supports all the operations that :class:`TensorType`
    supports.

    See Also
    --------
    SharedVariable

    """

    def get_value(self, borrow=False, return_internal_type=False):
        if return_internal_type:
            if borrow:
                return self.container.value
            else:
                return self.container.value.copy()
        else:
            return np.asarray(self.container.value)

    def set_value(self, value, borrow=False):
        if isinstance(value, pygpu.gpuarray.GpuArray):
            value = pygpu.gpuarray.array(
                value, copy=(not borrow), context=self.type.context
            )
        self.container.value = value

    def __getitem__(self, *args):
        return _operators.__getitem__(self, *args)


GpuArrayType.SharedVariable = GpuArraySharedVariable
notset = object()


def gpuarray_shared_constructor(
    value,
    name=None,
    strict=False,
    allow_downcast=None,
    borrow=False,
    broadcastable=None,
    target=notset,
):
    """
    SharedVariable constructor for GpuArrayType.

    See :func:`aesara.shared`.

    :target: default None
        The device target. As None is a valid value and we need to
        differentiate from the parameter notset and None, we use a
        notset object.

    """
    if target == "cpu":
        raise TypeError("not for me")

    if not isinstance(value, (np.ndarray, pygpu.gpuarray.GpuArray)):
        raise TypeError("ndarray or GpuArray required")

    if target is notset:
        target = None
        if not gpu_supported(value):
            raise TypeError("The GPU do not support that value.")
        if not move_to_gpu(value):
            raise TypeError("We do not move that data by default to the GPU")
    try:
        get_context(target)
    except ContextNotDefined:
        # Don't make this a hard error if we attempt to make a shared
        # variable while there is no default context.
        if target is None:
            raise TypeError("No default context and no context specified")
        raise

    if broadcastable is None:
        broadcastable = (False,) * value.ndim
    type = GpuArrayType(value.dtype, broadcastable, context_name=target)
    deviceval = pygpu.gpuarray.array(value, copy=(not borrow), context=type.context)
    return GpuArraySharedVariable(type=type, value=deviceval, name=name, strict=strict)


aesara.compile.register_view_op_c_code(
    GpuArrayType,
    """
    Py_XDECREF(%(oname)s);
    %(oname)s = %(iname)s;
    Py_XINCREF(%(oname)s);
""",
    version=(0,),
)

# Register GpuArrayType C code for Shape Op.
register_shape_c_code(
    GpuArrayType,
    """
    npy_intp shape[] = {%(iname)s->ga.nd};
    if(%(oname)s == NULL || (PyArray_DIMS(%(oname)s)[0] != shape[0]))
    {
        Py_XDECREF(%(oname)s);
        %(oname)s = (PyArrayObject*) PyArray_SimpleNew(1, shape, NPY_INT64);
    }
    for(int i=0;i<shape[0];i++)
    {
        ((npy_int64*)PyArray_GETPTR1(%(oname)s, i))[0] = %(iname)s->ga.dimensions[i];
    }
    """,
    version=1,
)

register_shape_i_c_code(
    GpuArrayType,
    """
    if(!%(oname)s)
        %(oname)s=(PyArrayObject*)PyArray_ZEROS(0, NULL, NPY_INT64, 0);
    ((npy_int64*)PyArray_DATA(%(oname)s))[0] =
                              %(iname)s->ga.dimensions[%(i)s];
    """,
    """
    if (%(i)s>=%(iname)s->ga.nd){
        PyErr_SetString(PyExc_TypeError,
            "Number of dimensions lower than expected");
        %(fail)s
    }
    """,
    version=(1,),
)

aesara.compile.register_deep_copy_op_c_code(
    GpuArrayType,
    """
    Py_XDECREF(%(oname)s);
    %(oname)s = pygpu_copy(%(iname)s, GA_ANY_ORDER);
    if (!%(oname)s) { %(fail)s }
""",
    version=(5,),
)

aesara.tensor.basic.register_rebroadcast_c_code(
    GpuArrayType,
    """
    if(%(iname)s->ga.dimensions[%(axis)s] != 1){
        PyErr_Format(PyExc_ValueError,
            "Dimension %(axis)s in Rebroadcast's input was"
            " supposed to be 1 (got %%d instead)",
            %(iname)s->ga.dimensions[%(axis)s]);
        %(fail)s
    }
    """,
    version=1,
)

register_specify_shape_c_code(
    GpuArrayType,
    """
        if (PyGpuArray_NDIM(%(iname)s) != PyArray_DIMS(%(shape)s)[0]) {
            PyErr_Format(PyExc_AssertionError,
                         "SpecifyShape: vector of shape has %%d elements,"
                         " but the input has %%d dimensions.",
                         PyGpuArray_NDIM(%(iname)s),
                         PyArray_DIMS(%(shape)s)[0]);
            %(fail)s;
        }
        for(int i = 0; i < PyGpuArray_NDIM(%(iname)s); i++){
            dtype_%(shape)s shp = ((dtype_%(shape)s*)PyArray_GETPTR1(%(shape)s,
                                                                     i))[0];
            if (PyGpuArray_DIMS(%(iname)s)[i] != shp) {
                PyErr_Format(PyExc_AssertionError,
                             "SpecifyShape: dim %%d of input has shape %%d,"
                             " expected %%d.",
                             i, PyGpuArray_DIMS(%(iname)s)[i],
                             shp);
                %(fail)s;
            }
        }
        Py_XDECREF(%(oname)s);
        %(oname)s = %(iname)s;
        Py_XINCREF(%(oname)s);
    """,
    version=1,
    c_support_code_apply="#include <numpy_compat.h>",
)


class GpuContextType(CType):
    """
    Minimal type used for passing contexts to nodes.

    This Type is not a complete type and should never be used for
    regular graph operations.

    """

    def filter(self, data, strict=False, allow_downcast=None):
        if not isinstance(data, gpuarray.GpuContext):
            raise TypeError("context is not a GpuContext")
        return data

    def __eq__(self, other):
        return type(self) == type(other)

    def __hash__(self):
        return hash(type(self))

    @staticmethod
    def values_eq(a, b):
        return a == b

    def c_declare(self, name, sub, check_input=True):
        return f"PyGpuContextObject *{name};"

    def c_init(self, name, sub):
        return f"{name} = NULL;"

    def c_extract(self, name, sub, check_input=True, **kwargs):
        if check_input:
            res = """
if (!PyObject_TypeCheck(py_%(name)s, &PyGpuContextType)) {
  PyErr_SetString(PyExc_TypeError, "expected a GpuContext");
  %(fail)s
}
""" % dict(
                name=name, fail=sub["fail"]
            )
        else:
            res = ""
        return (
            res
            + """
%(name)s = (PyGpuContextObject *)py_%(name)s;
Py_INCREF(%(name)s);
"""
            % dict(name=name)
        )

    def c_cleanup(self, name, sub):
        return f"Py_XDECREF({name}); {name} = NULL;"

    def c_sync(self, name, sub):
        # c_sync is intentionally not declared to prevent normal usage
        raise NotImplementedError("Variables of this type cannot be graph outputs")

    def c_init_code(self, **kwargs):
        return ["import_pygpu__gpuarray();"]

    def c_headers(self, **kwargs):
        return ["<gpuarray_api.h>"]

    def c_header_dirs(self, **kwargs):
        return [pygpu.get_include()]

    def c_code_cache_version(self):
        ver = pygpu.gpuarray.api_version()
        return (0, ver[0])

    # Variable, Contstant, ... not declared


"""
Instance of :class:`GpuContextType` to use for the context_type
declaration of an operation.
"""
gpu_context_type = GpuContextType()


# THIS WORKS But GpuArray instances don't compare equal to one
# another, and what about __hash__ ?  So the unpickled version doesn't
# equal the pickled version, and the cmodule cache is not happy with
# the situation. The old back-end have this same comment and use the
# same mechanism.
def GpuArray_unpickler(npa, ctx_name):
    if config.experimental__unpickle_gpu_on_cpu:
        # directly return numpy array
        warnings.warn(
            "config.experimental__unpickle_gpu_on_cpu is set to True. "
            "Unpickling GpuArray as numpy.ndarray"
        )
        return npa
    elif pygpu:
        ctx = get_context(ctx_name)
        return pygpu.gpuarray.array(npa, copy=True, context=ctx)
    else:
        raise ImportError("pygpu not found. Cannot unpickle GpuArray")


copyreg.constructor(GpuArray_unpickler)


def GpuArray_pickler(cnda):
    ctx_name = _name_for_ctx(cnda.context)
    return (GpuArray_unpickler, (np.asarray(cnda), ctx_name))


# In case pygpu is not imported.
if pygpu is not None:
    copyreg.pickle(pygpu.gpuarray.GpuArray, GpuArray_pickler, GpuArray_unpickler)
